Organismal Biology/33D3-ProtostomiaEcdysozoa

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Transcript Organismal Biology/33D3-ProtostomiaEcdysozoa

CHAPTER 33
INVERTEBRATES
Section D3: Protostomia: Ecdysozoa (continued)
2. Arthropods are segmented coelomates with exoskeletons and jointed
appendages (continued)
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• Metamorphosis is central to insect development.
• In incomplete metamorphosis (seen in grasshoppers and
some other orders), the young resemble adults but are
smaller and have different body proportions.
• Through a series of molts, the young look more and
more like adults until it reaches full size.
• In complete metamorphosis, larval stages specialized
for eating and growing change morphology completely
during the pupal stage and emerge as adults.
Fig. 33.34
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• Reproduction in insects is usually sexual, with
separate male and female individuals.
• Coloration, sound, or odor bring together opposite sexes
at the appropriate time.
• In most species, sperm cells are deposited directly into
the female’s vagina at the time of copulation.
• In a few species, females pick up a sperm packet
deposited by a male.
• The females store sperm in the spermatheca, in some
cases holding enough sperm from a single mating to last a
lifetime.
• After mating, females lay their eggs on a food source
appropriate for the next generation.
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• Insects affect the lives of all other terrestrial
organisms.
• Insects are important natural and agricultural
pollinators.
• On the other hand, insects are carriers for many
diseases, including malaria and African sleeping
sickness.
• Insects compete with humans for food, consuming
crops intended to feed and clothe human populations.
• Billions of dollars each year are spent by farmers on
pesticides to minimize their losses to insects.
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• While arachnids and insects thrive on land, most of
the 40,000 species of crustaceans remain in marine
and freshwater environments.
• A few crustaceans are terrestrial or semi-terrestrial.
• Crustaceans include lobsters, crabs, crayfish, shrimp, and
barnacles, among
many others.
Fig. 33.35
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• The multiple appendages of crustaceans are
extensively specialized.
• For instance, lobsters and crayfish have 19 pairs of
appendages, adapted to a variety of tasks.
• In addition to two pairs of antennae, crustaceans have
three or more pairs of mouth parts, including hard
mandibles.
• Walking legs are present on the thorax and other
appendages for swimming or reproduction are found on
the abdomen.
• Crustaceans can regenerate lost appendages during
molting.
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• Small crustaceans exchange gases across thin areas
of the cuticle, but larger species have gills.
• The circulatory system is open, with a heat pumping
hemolymph into short arteries and then into sinuses
that bathe the organs.
• Nitrogenous wastes are excreted by diffusion
through thin areas of the cuticle, but glands regulate
the salt balance of the hemolymph.
• Most crustaceans have separate sexes.
• Males use a specialized pair of appendages to transfer
sperm to the female’s reproductive pore.
• Most aquatic species have several larval stages.
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• The isopods, with about 10,000 species, are one of
the largest groups of crustaceans.
• Most are small marine species, but they can be
abundant at the bottom of deep oceans.
• They also include the land-dwelling pill bugs, or wood
lice, that live underneath moist logs and leaves.
• The copepods are among the most numerous of all
animals.
• These small crustaceans are important members of
marine and freshwater plankton communities, eating
protists and bacteria and being eaten by may fishes.
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• Decapods, including lobsters, crayfish, crabs, and
shrimp, are among the largest crustaceans.
• The cuticle is hardened with calcium carbonate.
• The exoskeleton over the cephalothorax forms a shield
called the carapace.
• While most decapods are marine, crayfish live in
freshwater and some tropical crabs are terrestrial as
adults.
• Related to decapods, krill are shrimplike planktonic
organisms that reach about 3 cm long.
• A major food source for whales and other ocean
predators, they are now harvested extensively by humans
for food and agricultural fertilizer.
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• Barnacles are sessile crustaceans with parts of their
cuticle hardened by calcium carbonate.
• They strain food from the water by extending their
appendages.
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• The revision of the invertebrate phyla into the
Lophotrochozoa and the Ecdysozoa has raised the
issue of how often segmentation evolved in the
animal kingdom.
• Until recently, the majority of biologists favored the
hypothesis that arthropods evolved from the segmented
annelids, or that both groups evolved from a common
segmented ancestor.
• The molecular data would split these phyla into two
different parts of the animal phylogenetic tree.
• This conflict has focused interest in the evolutionary
origin of segmentation.
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• The segmented bodies of arthropods and annelids,
represents a special case of a more general
phenomenon: the blocking-out of an embryo into
regions where certain body parts will develop.
• Differential expression of various regulatory genes that
code for transcription factors plays a key role in this
blocking-out of anterior -> posterior anatomy in the
developing embryo.
• For example, differential expression of various Hox
genes along the length of the lobster embryo cause
antennae to develop on certain segments and walking
legs on others.
• Hox genes are also present in nonsegmented animals
and play an important role in development.
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• An increase in Hox gene number through gene
duplication and mutations, along with adaptation
of Hox gene function for the development of
segmented bodies, made it possible for a great
diversity of complex animals to evolve.
• Body segmentation evolved in several of the 35
animal phyla, including annelids, arthropods, and
chordates.
• Segmented animals occur in all three major clades
of bilaterians.
• Each clade also includes nonsegmented animals.
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• Three hypotheses can account for the scattered
distribution of segmentation among animal phyla.
• In the first, segmentation had separate evolutionary
origins in each bilaterian clade.
Fig. 33.36a
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• In the second, there were two separate origins of
segmentation, one for the protostomes and one for
the deuterostomes.
• Some phyla in the protostomes then lost segmentation.
Fig. 33.36b
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• In the third, segmentation evolved just once, in a
common ancestor to all three bilaterian lineages.
• Several phyla in each group then lost segmentation.
Fig. 33.36c
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• The principle of parsimony would seem to favor the
first hypothesis because it involves the fewest
evolutionary changes.
• However, application of parsimony is merely an
analytical aid in cladistics, not a law of evolution that life
always follows.
• Without more evidence, all three hypotheses remain
plausible explanations for the distribution of
segmentation among animal phyla.
• “Evo-devo,” at the interface of evolutionary biology
and developmental biology, may answer some of
these questions by comparing the roles of various
regulatory genes during development.
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